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3. Sperm Deliver a New Second Messenger NAADP

Author

Churchill, GC, O'Neill, JS, Masgrau, R, Patel, S, Thomas, JM, Genazzani, AA, and Galione, A

Abstract

NAADP is a highly potent mobilizer of Ca2+[1, 2], which in turn triggers Ca2+-induced Ca2+ release pathways [3–6] in a wide range of species [2, 7]. Nevertheless, NAADP is not presently classified as a second messenger because it has not been shown to increase in response to a physiological stimulus. We now report a dramatic increase in NAADP during sea urchin egg fertilization that was largely due to production in sperm upon contacting egg jelly. The NAADP bolus plays a physiological role upon delivery to the egg based on its ability to induce a cortical flash, a depolarization-induced activation of L-type Ca2+ channels. Moreover, the sperm-induced cortical flash was eliminated in eggs desensitized to NAADP. We conclude that an NAADP increase plays a physiologically relevant role during fertilization and provides the first conclusive demonstration that NAADP is a genuine second messenger.

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5. Mammalian Circadian Period, But Not Phase and Amplitude, Is Robust Against Redox and Metabolic Perturbations

Author

Putker, M, Crosby, P, Feeney, KA, Hoyle, NP, Costa, ASH, Gaude, E, Frezza, C, and O'Neill, JS

Subjects
circadian rhythm, clock gene, primary metabolism, mammalian, pentose phosphate pathway, redox signaling, 3. Good health
Abstract

$\textit{Aims:}$ Circadian rhythms permeate all levels of biology to temporally regulate cell and whole-body physiology, although the cell-autonomous mechanism that confers ~24-h periodicity is incompletely understood. Reports describing circadian oscillations of over-oxidized peroxiredoxin abundance have suggested that redox signaling plays an important role in the timekeeping mechanism. Here, we tested the functional contribution that redox state and primary metabolism make to mammalian cellular timekeeping. $\textit{Results:}$ We found a circadian rhythm in flux through primary glucose metabolic pathways, indicating rhythmic NAD(P)H production. Using pharmacological and genetic perturbations, however, we found that timekeeping was insensitive to changes in glycolytic flux, whereas oxidative pentose phosphate pathway (PPP) inhibition and other chronic redox stressors primarily affected circadian gene expression amplitude, not periodicity. Finally, acute changes in redox state decreased PER2 protein stability, phase dependently, to alter the subsequent phase of oscillation. $\textit{Innovation:}$ Circadian rhythms in primary cellular metabolism and redox state have been proposed to play a role in the cellular timekeeping mechanism. We present experimental data testing that hypothesis. $\textit{Conclusion:}$ Circadian flux through primary metabolism is cell autonomous, driving rhythmic NAD(P)(+) redox cofactor turnover and maintaining a redox balance that is permissive for circadian gene expression cycles. Redox homeostasis and PPP flux, but not glycolysis, are necessary to maintain clock amplitude, but neither redox nor glucose metabolism determines circadian period. Furthermore, cellular rhythms are sensitive to acute changes in redox balance, at least partly through regulation of PER protein. Redox and metabolic state are, thus, both inputs and outputs, but not state variables, of cellular circadian timekeeping.

7. Circadian regulation of macromolecular complex turnover and proteome renewal.

Author

Seinkmane E, Edmondson A, Peak-Chew SY, Zeng A, Rzechorzek NM, James NR, West J, Munns J, Wong DC, Beale AD, and O'Neill JS

Subjects
Animals, Mice, Protein Biosynthesis, Humans, Proteasome Endopeptidase Complex metabolism, Ribosomes metabolism, Proteolysis, Proteostasis, Mice, Inbred C57BL, Circadian Rhythm physiology, Proteome metabolism
Abstract

Although costly to maintain, protein homeostasis is indispensable for normal cellular function and long-term health. In mammalian cells and tissues, daily variation in global protein synthesis has been observed, but its utility and consequences for proteome integrity are not fully understood. Using several different pulse-labelling strategies, here we gain direct insight into the relationship between protein synthesis and abundance proteome-wide. We show that protein degradation varies in-phase with protein synthesis, facilitating rhythms in turnover rather than abundance. This results in daily consolidation of proteome renewal whilst minimising changes in composition. Coupled rhythms in synthesis and turnover are especially salient to the assembly of macromolecular protein complexes, particularly the ribosome, the most abundant species of complex in the cell. Daily turnover and proteasomal degradation rhythms render cells and mice more sensitive to proteotoxic stress at specific times of day, potentially contributing to daily rhythms in the efficacy of proteasomal inhibitors against cancer. Our findings suggest that circadian rhythms function to minimise the bioenergetic cost of protein homeostasis through temporal consolidation of protein turnover., (© 2024. The Author(s).)

Published
2024
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8. Potassium rhythms couple the circadian clock to the cell cycle.

Author

Rodríguez SG, Crosby P, Hansen LL, Grünewald E, Beale AD, Spangler RK, Rabbitts BM, Partch CL, Stangherlin A, O'Neill JS, and van Ooijen G

Abstract

Circadian (~24 h) rhythms are a fundamental feature of life, and their disruption increases the risk of infectious diseases, metabolic disorders, and cancer 1-6 . Circadian rhythms couple to the cell cycle across eukaryotes 7,8 but the underlying mechanism is unknown. We previously identified an evolutionarily conserved circadian oscillation in intracellular potassium concentration, [K + ] i 9,10 . As critical events in the cell cycle are regulated by intracellular potassium 11,12 , an enticing hypothesis is that circadian rhythms in [K + ] i form the basis of this coupling. We used a minimal model cell, the alga Ostreococcus tauri , to uncover the role of potassium in linking these two cycles. We found direct reciprocal feedback between [K + ] i and circadian gene expression. Inhibition of proliferation by manipulating potassium rhythms was dependent on the phase of the circadian cycle. Furthermore, we observed a total inhibition of cell proliferation when circadian gene expression is inhibited. Strikingly, under these conditions a sudden enforced gradient of extracellular potassium was sufficient to induce a round of cell division. Finally, we provide evidence that interactions between potassium and circadian rhythms also influence proliferation in mammalian cells. These results establish circadian regulation of intracellular potassium levels as a primary factor coupling the cell- and circadian cycles across diverse organisms.

Published
2024
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9. Author Correction: Macromolecular condensation buffers intracellular water potential.

Author

Watson JL, Seinkmane E, Styles CT, Mihut A, Krüger LK, McNally KE, Planelles-Herrero VJ, Dudek M, McCall PM, Barbiero S, Vanden Oever M, Peak-Chew SY, Porebski BT, Zeng A, Rzechorzek NM, Wong DCS, Beale AD, Stangherlin A, Riggi M, Iwasa J, Morf J, Miliotis C, Guna A, Inglis AJ, Brugués J, Voorhees RM, Chambers JE, Meng QJ, O'Neill JS, Edgar RS, and Derivery E

Published
2024
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10. Propylene glycol inactivates respiratory viruses and prevents airborne transmission.

Author

Styles CT, Zhou J, Flight KE, Brown JC, Lewis C, Wang X, Vanden Oever M, Peacock TP, Wang Z, Millns R, O'Neill JS, Borodavka A, Grove J, Barclay WS, Tregoning JS, and Edgar RS

Subjects
Animals, Mice, Humans, Respiratory Aerosols and Droplets, Propylene Glycols, Mammals, Influenza, Human, Influenza A virus, COVID-19 prevention & control
Abstract

Viruses are vulnerable as they transmit between hosts, and we aimed to exploit this critical window. We found that the ubiquitous, safe, inexpensive and biodegradable small molecule propylene glycol (PG) has robust virucidal activity. Propylene glycol rapidly inactivates a broad range of viruses including influenza A, SARS-CoV-2 and rotavirus and reduces disease burden in mice when administered intranasally at concentrations commonly found in nasal sprays. Most critically, vaporised PG efficiently abolishes influenza A virus and SARS-CoV-2 infectivity within airborne droplets, potently preventing infection at levels well below those tolerated by mammals. We present PG vapour as a first-in-class non-toxic airborne virucide that can prevent transmission of existing and emergent viral pathogens, with clear and immediate implications for public health., (© 2023 The Authors. Published under the terms of the CC BY 4.0 license.)

Published
2023
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11. Macromolecular condensation buffers intracellular water potential.

Author

Watson JL, Seinkmane E, Styles CT, Mihut A, Krüger LK, McNally KE, Planelles-Herrero VJ, Dudek M, McCall PM, Barbiero S, Vanden Oever M, Peak-Chew SY, Porebski BT, Zeng A, Rzechorzek NM, Wong DCS, Beale AD, Stangherlin A, Riggi M, Iwasa J, Morf J, Miliotis C, Guna A, Inglis AJ, Brugués J, Voorhees RM, Chambers JE, Meng QJ, O'Neill JS, Edgar RS, and Derivery E

Subjects
Cell Death, Cytosol chemistry, Cytosol metabolism, Homeostasis, Osmolar Concentration, Pressure, Temperature, Time Factors, Macromolecular Substances chemistry, Macromolecular Substances metabolism, Proteins chemistry, Proteins metabolism, Solvents chemistry, Solvents metabolism, Thermodynamics, Water chemistry, Water metabolism
Abstract

Optimum protein function and biochemical activity critically depends on water availability because solvent thermodynamics drive protein folding and macromolecular interactions 1 . Reciprocally, macromolecules restrict the movement of 'structured' water molecules within their hydration layers, reducing the available 'free' bulk solvent and therefore the total thermodynamic potential energy of water, or water potential. Here, within concentrated macromolecular solutions such as the cytosol, we found that modest changes in temperature greatly affect the water potential, and are counteracted by opposing changes in osmotic strength. This duality of temperature and osmotic strength enables simple manipulations of solvent thermodynamics to prevent cell death after extreme cold or heat shock. Physiologically, cells must sustain their activity against fluctuating temperature, pressure and osmotic strength, which impact water availability within seconds. Yet, established mechanisms of water homeostasis act over much slower timescales 2,3 ; we therefore postulated the existence of a rapid compensatory response. We find that this function is performed by water potential-driven changes in macromolecular assembly, particularly biomolecular condensation of intrinsically disordered proteins. The formation and dissolution of biomolecular condensates liberates and captures free water, respectively, quickly counteracting thermal or osmotic perturbations of water potential, which is consequently robustly buffered in the cytoplasm. Our results indicate that biomolecular condensation constitutes an intrinsic biophysical feedback response that rapidly compensates for intracellular osmotic and thermal fluctuations. We suggest that preserving water availability within the concentrated cytosol is an overlooked evolutionary driver of protein (dis)order and function., (© 2023. The Author(s).)

Published
2023
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12. Mechanisms and physiological function of daily haemoglobin oxidation rhythms in red blood cells.

Author

Beale AD, Hayter EA, Crosby P, Valekunja UK, Edgar RS, Chesham JE, Maywood ES, Labeed FH, Reddy AB, Wright KP Jr, Lilley KS, Bechtold DA, Hastings MH, and O'Neill JS

Subjects
Humans, Mice, Animals, Oxidation-Reduction, Heme metabolism, Circadian Rhythm, Erythrocytes metabolism, Hemoglobins metabolism
Abstract

Cellular circadian rhythms confer temporal organisation upon physiology that is fundamental to human health. Rhythms are present in red blood cells (RBCs), the most abundant cell type in the body, but their physiological function is poorly understood. Here, we present a novel biochemical assay for haemoglobin (Hb) oxidation status which relies on a redox-sensitive covalent haem-Hb linkage that forms during SDS-mediated cell lysis. Formation of this linkage is lowest when ferrous Hb is oxidised, in the form of ferric metHb. Daily haemoglobin oxidation rhythms are observed in mouse and human RBCs cultured in vitro, or taken from humans in vivo, and are unaffected by mutations that affect circadian rhythms in nucleated cells. These rhythms correlate with daily rhythms in core body temperature, with temperature lowest when metHb levels are highest. Raising metHb levels with dietary sodium nitrite can further decrease daytime core body temperature in mice via nitric oxide (NO) signalling. These results extend our molecular understanding of RBC circadian rhythms and suggest they contribute to the regulation of body temperature., (© 2023 The Authors. Published under the terms of the CC BY 4.0 license.)

Published
2023
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14. A daily temperature rhythm in the human brain predicts survival after brain injury.

Author

Rzechorzek NM, Thrippleton MJ, Chappell FM, Mair G, Ercole A, Cabeleira M, Rhodes J, Marshall I, and O'Neill JS

Subjects
Adult, Aged, Body Temperature physiology, Brain physiology, Female, Humans, Male, Retrospective Studies, Temperature, Brain Injuries complications, Brain Injuries, Traumatic complications, Hypothermia, Induced
Abstract

Patients undergo interventions to achieve a 'normal' brain temperature; a parameter that remains undefined for humans. The profound sensitivity of neuronal function to temperature implies the brain should be isothermal, but observations from patients and non-human primates suggest significant spatiotemporal variation. We aimed to determine the clinical relevance of brain temperature in patients by establishing how much it varies in healthy adults. We retrospectively screened data for all patients recruited to the Collaborative European NeuroTrauma Effectiveness Research in Traumatic Brain Injury (CENTER-TBI) High Resolution Intensive Care Unit Sub-Study. Only patients with direct brain temperature measurements and without targeted temperature management were included. To interpret patient analyses, we prospectively recruited 40 healthy adults (20 males, 20 females, 20-40 years) for brain thermometry using magnetic resonance spectroscopy. Participants were scanned in the morning, afternoon, and late evening of a single day. In patients (n = 114), brain temperature ranged from 32.6 to 42.3°C and mean brain temperature (38.5 ± 0.8°C) exceeded body temperature (37.5 ± 0.5°C, P < 0.0001). Of 100 patients eligible for brain temperature rhythm analysis, 25 displayed a daily rhythm, and the brain temperature range decreased in older patients (P = 0.018). In healthy participants, brain temperature ranged from 36.1 to 40.9°C; mean brain temperature (38.5 ± 0.4°C) exceeded oral temperature (36.0 ± 0.5°C) and was 0.36°C higher in luteal females relative to follicular females and males (P = 0.0006 and P < 0.0001, respectively). Temperature increased with age, most notably in deep brain regions (0.6°C over 20 years, P = 0.0002), and varied spatially by 2.41 ± 0.46°C with highest temperatures in the thalamus. Brain temperature varied by time of day, especially in deep regions (0.86°C, P = 0.0001), and was lowest at night. From the healthy data we built HEATWAVE-a 4D map of human brain temperature. Testing the clinical relevance of HEATWAVE in patients, we found that lack of a daily brain temperature rhythm increased the odds of death in intensive care 21-fold (P = 0.016), whilst absolute temperature maxima or minima did not predict outcome. A warmer mean brain temperature was associated with survival (P = 0.035), however, and ageing by 10 years increased the odds of death 11-fold (P = 0.0002). Human brain temperature is higher and varies more than previously assumed-by age, sex, menstrual cycle, brain region, and time of day. This has major implications for temperature monitoring and management, with daily brain temperature rhythmicity emerging as one of the strongest single predictors of survival after brain injury. We conclude that daily rhythmic brain temperature variation-not absolute brain temperature-is one way in which human brain physiology may be distinguished from pathophysiology., (© The Author(s) 2022. Published by Oxford University Press on behalf of the Guarantors of Brain.)

Published
2022
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15. CRYPTOCHROMES promote daily protein homeostasis.

Author

Wong DCS, Seinkmane E, Zeng A, Stangherlin A, Rzechorzek NM, Beale AD, Day J, Reed M, Peak-Chew SY, Styles CT, Edgar RS, Putker M, and O'Neill JS

Subjects
Animals, Cryptochromes deficiency, Ion Transport, Mice, Phosphoproteins metabolism, Proteasome Endopeptidase Complex metabolism, Proteome metabolism, Proteomics, Reproducibility of Results, Stress, Physiological, Time Factors, Circadian Rhythm physiology, Cryptochromes metabolism, Proteostasis
Abstract

The daily organisation of most mammalian cellular functions is attributed to circadian regulation of clock-controlled protein expression, driven by daily cycles of CRYPTOCHROME-dependent transcriptional feedback repression. To test this, we used quantitative mass spectrometry to compare wild-type and CRY-deficient fibroblasts under constant conditions. In CRY-deficient cells, we found that temporal variation in protein, phosphopeptide, and K + abundance was at least as great as wild-type controls. Most strikingly, the extent of temporal variation within either genotype was much smaller than overall differences in proteome composition between WT and CRY-deficient cells. This proteome imbalance in CRY-deficient cells and tissues was associated with increased susceptibility to proteotoxic stress, which impairs circadian robustness, and may contribute to the wide-ranging phenotypes of CRY-deficient mice. Rather than generating large-scale daily variation in proteome composition, we suggest it is plausible that the various transcriptional and post-translational functions of CRY proteins ultimately act to maintain protein and osmotic homeostasis against daily perturbation., (© 2021 MRC Laboratory of Molecular Biology. Published under the terms of the CC BY 4.0 license.)

Published
2022
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16. Detecting Circadian Rhythms in Human Red Blood Cells by Dielectrophoresis.

Author

Beale AD, Labeed FH, Kitcatt SJ, and O'Neill JS

Subjects
Electrophysiological Phenomena, Humans, Circadian Rhythm physiology, Erythrocytes metabolism
Abstract

Dielectrophoresis (DEP) enables the measurement of population-level electrophysiology in many cell types by examining their interaction with an externally applied electric field. Here we describe the application of DEP to the measurement of circadian rhythms in a non-nucleated cell type, the human red blood cell. Using DEP, population-level electrophysiology of ~20,000 red blood cells can be measured from start to finish in less than 3 min, and can be repeated over several days to reveal cell-autonomous daily regulation of membrane electrophysiology. This method is amenable to the characterization of circadian rhythms by altering entrainment and free-run conditions or through pharmacological perturbation., (© 2022. The Author(s).)

Published
2022
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17. Using ALLIGATORs to Capture Circadian Bioluminescence.

Author

Zeng A and O'Neill JS

Subjects
Animals, Circadian Rhythm physiology, Luciferases genetics, Luciferases metabolism, Luminescent Measurements methods, Temperature, Alligators and Crocodiles, Circadian Clocks
Abstract

Luciferases are a popular tool in circadian biology research as longitudinal reporters of gene expression. Here, we describe a short updated protocol for the use of an Automated Longitudinal Luciferase Imaging Gas and Temperature-Optimized Recorder (ALLIGATOR) to record cellular bioluminescence over many days. The ALLIGATOR has superior capacity and flexibility compared with traditional luminometers that employ photomultiplier tubes (PMTs), with high-throughput capability and spatial resolution. It can be readily adapted to a wide variety of applications, such as different sample types and plate sizes, under a wide range of physiologically relevant conditions., (© 2022. The Author(s).)

Published
2022
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20. Understanding circadian regulation of mammalian cell function, protein homeostasis, and metabolism.

Author

Stangherlin A, Seinkmane E, and O'Neill JS

Abstract

Circadian rhythms are ∼24 h cycles of organismal and cellular activity ubiquitous to mammalian physiology. A prevailing paradigm suggests that timing information flows linearly from rhythmic transcription via protein abundance changes to drive circadian regulation of cellular function. Challenging this view, recent evidence indicates daily variation in many cellular functions arises through rhythmic post-translational regulation of protein activity. We suggest cellular circadian timing primarily functions to maintain proteome homeostasis rather than perturb it. Indeed, although relevant to timekeeping mechanism, daily rhythms of clock protein abundance may be the exception, not the rule. Informed by insights from yeast and mammalian models, we propose that optimal bioenergetic efficiency results from coupled rhythms in mammalian target of rapamycin complex activity, protein synthesis/turnover, ion transport and protein sequestration, which drive facilitatory rhythms in metabolic flux and substrate utilisation. Such daily consolidation of proteome renewal would account for many aspects of circadian cell biology whilst maintaining osmotic homeostasis., Competing Interests: Nothing declared., (© 2021 MRC Laboratory of Molecular Biology.)

Published
2021
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22. Compensatory ion transport buffers daily protein rhythms to regulate osmotic balance and cellular physiology.

Author

Stangherlin A, Watson JL, Wong DCS, Barbiero S, Zeng A, Seinkmane E, Chew SP, Beale AD, Hayter EA, Guna A, Inglis AJ, Putker M, Bartolami E, Matile S, Lequeux N, Pons T, Day J, van Ooijen G, Voorhees RM, Bechtold DA, Derivery E, Edgar RS, Newham P, and O'Neill JS

Subjects
Animals, Cardiovascular System pathology, Cells, Cultured, Chlorides metabolism, Fibroblasts, Homeostasis, Lung, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, Potassium metabolism, Proteome, Sodium metabolism, Solute Carrier Family 12, Member 2 genetics, Cell Physiological Phenomena, Circadian Rhythm physiology, Ion Transport physiology, Osmosis
Abstract

Between 6-20% of the cellular proteome is under circadian control and tunes mammalian cell function with daily environmental cycles. For cell viability, and to maintain volume within narrow limits, the daily variation in osmotic potential exerted by changes in the soluble proteome must be counterbalanced. The mechanisms and consequences of this osmotic compensation have not been investigated before. In cultured cells and in tissue we find that compensation involves electroneutral active transport of Na + , K + , and Cl - through differential activity of SLC12A family cotransporters. In cardiomyocytes ex vivo and in vivo, compensatory ion fluxes confer daily variation in electrical activity. Perturbation of soluble protein abundance has commensurate effects on ion composition and cellular function across the circadian cycle. Thus, circadian regulation of the proteome impacts ion homeostasis with substantial consequences for the physiology of electrically active cells such as cardiomyocytes., (© 2021. Crown.)

Published
2021
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23. Deep-coverage spatiotemporal proteome of the picoeukaryote Ostreococcus tauri reveals differential effects of environmental and endogenous 24-hour rhythms.

Author

Kay H, Grünewald E, Feord HK, Gil S, Peak-Chew SY, Stangherlin A, O'Neill JS, and van Ooijen G

Subjects
Algal Proteins metabolism, Chlorophyta genetics, Proteome metabolism, Spatio-Temporal Analysis, Algal Proteins genetics, Chlorophyta physiology, Environment, Periodicity, Proteome genetics
Abstract

The cellular landscape changes dramatically over the course of a 24 h day. The proteome responds directly to daily environmental cycles and is additionally regulated by the circadian clock. To quantify the relative contribution of diurnal versus circadian regulation, we mapped proteome dynamics under light:dark cycles compared with constant light. Using Ostreococcus tauri, a prototypical eukaryotic cell, we achieved 85% coverage, which allowed an unprecedented insight into the identity of proteins that facilitate rhythmic cellular functions. The overlap between diurnally- and circadian-regulated proteins was modest and these proteins exhibited different phases of oscillation between the two conditions. Transcript oscillations were generally poorly predictive of protein oscillations, in which a far lower relative amplitude was observed. We observed coordination between the rhythmic regulation of organelle-encoded proteins with the nuclear-encoded proteins that are targeted to organelles. Rhythmic transmembrane proteins showed a different phase distribution compared with rhythmic soluble proteins, indicating the existence of a circadian regulatory process specific to the biogenesis and/or degradation of membrane proteins. Our observations argue that the cellular spatiotemporal proteome is shaped by a complex interaction between intrinsic and extrinsic regulatory factors through rhythmic regulation at the transcriptional as well as post-transcriptional, translational, and post-translational levels., (© 2021. The Author(s).)

Published
2021
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24. Targeted modification of the Per2 clock gene alters circadian function in mPer2luciferase (mPer2Luc) mice.

Author

Ralph MR, Shi SQ, Johnson CH, Houdek P, Shrestha TC, Crosby P, O'Neill JS, Sládek M, Stinchcombe AR, and Sumová A

Subjects
Animals, Behavior, Animal, Feeding Behavior, Locomotion, Mice, Mice, Inbred C57BL, Mutation, Circadian Rhythm, Luciferases genetics, Period Circadian Proteins genetics
Abstract

Modification of the Per2 clock gene in mPer2Luc reporter mice significantly alters circadian function. Behavioral period in constant dark is lengthened, and dissociates into two distinct components in constant light. Rhythms exhibit increased bimodality, enhanced phase resetting to light pulses, and altered entrainment to scheduled feeding. Mechanistic mathematical modelling predicts that enhanced protein interactions with the modified mPER2 C-terminus, combined with differential clock regulation among SCN subregions, can account for effects on circadian behavior via increased Per2 transcript and protein stability. PER2::LUC produces greater suppression of CLOCK:BMAL1 E-box activity than PER2. mPer2Luc carries a 72 bp deletion in exon 23 of Per2, and retains a neomycin resistance cassette that affects rhythm amplitude but not period. The results show that mPer2Luc acts as a circadian clock mutation illustrating a need for detailed assessment of potential impacts of c-terminal tags in genetically modified animal models., Competing Interests: The authors have declared that no competing interests exist.

Published
2021
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25. Distinct circadian mechanisms govern cardiac rhythms and susceptibility to arrhythmia.

Author

Hayter EA, Wehrens SMT, Van Dongen HPA, Stangherlin A, Gaddameedhi S, Crooks E, Barron NJ, Venetucci LA, O'Neill JS, Brown TM, Skene DJ, Trafford AW, and Bechtold DA

Subjects
ARNTL Transcription Factors genetics, ARNTL Transcription Factors metabolism, Adult, Animals, Arrhythmias, Cardiac genetics, Arrhythmias, Cardiac metabolism, Atrioventricular Node metabolism, Autonomic Nervous System physiology, Circadian Clocks physiology, Electrocardiography, Female, Gene Expression Regulation genetics, Gene Expression Regulation physiology, Humans, Male, Mice, Mice, Transgenic, Middle Aged, Myocytes, Cardiac metabolism, Sinoatrial Node metabolism, Sleep physiology, Arrhythmias, Cardiac physiopathology, Atrioventricular Node physiology, Circadian Rhythm physiology, Heart Rate physiology, Myocytes, Cardiac physiology, Sinoatrial Node physiology
Abstract

Electrical activity in the heart exhibits 24-hour rhythmicity, and potentially fatal arrhythmias are more likely to occur at specific times of day. Here, we demonstrate that circadian clocks within the brain and heart set daily rhythms in sinoatrial (SA) and atrioventricular (AV) node activity, and impose a time-of-day dependent susceptibility to ventricular arrhythmia. Critically, the balance of circadian inputs from the autonomic nervous system and cardiomyocyte clock to the SA and AV nodes differ, and this renders the cardiac conduction system sensitive to decoupling during abrupt shifts in behavioural routine and sleep-wake timing. Our findings reveal a functional segregation of circadian control across the heart's conduction system and inherent susceptibility to arrhythmia.

Published
2021
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27. CRYPTOCHROMES confer robustness, not rhythmicity, to circadian timekeeping.

Author

Putker M, Wong DCS, Seinkmane E, Rzechorzek NM, Zeng A, Hoyle NP, Chesham JE, Edwards MD, Feeney KA, Fischer R, Peschel N, Chen KF, Vanden Oever M, Edgar RS, Selby CP, Sancar A, and O'Neill JS

Subjects
Animals, Cells, Cultured, Cryptochromes deficiency, Cryptochromes genetics, Drosophila melanogaster, Female, Locomotion, Male, Mice, Mice, Inbred C57BL, Period Circadian Proteins genetics, Period Circadian Proteins metabolism, Circadian Rhythm, Cryptochromes metabolism
Abstract

Circadian rhythms are a pervasive property of mammalian cells, tissues and behaviour, ensuring physiological adaptation to solar time. Models of cellular timekeeping revolve around transcriptional feedback repression, whereby CLOCK and BMAL1 activate the expression of PERIOD (PER) and CRYPTOCHROME (CRY), which in turn repress CLOCK/BMAL1 activity. CRY proteins are therefore considered essential components of the cellular clock mechanism, supported by behavioural arrhythmicity of CRY-deficient (CKO) mice under constant conditions. Challenging this interpretation, we find locomotor rhythms in adult CKO mice under specific environmental conditions and circadian rhythms in cellular PER2 levels when CRY is absent. CRY-less oscillations are variable in their expression and have shorter periods than wild-type controls. Importantly, we find classic circadian hallmarks such as temperature compensation and period determination by CK1δ/ε activity to be maintained. In the absence of CRY-mediated feedback repression and rhythmic Per2 transcription, PER2 protein rhythms are sustained for several cycles, accompanied by circadian variation in protein stability. We suggest that, whereas circadian transcriptional feedback imparts robustness and functionality onto biological clocks, the core timekeeping mechanism is post-translational., (© 2021 MRC Laboratory of Molecular Biology. Published under the terms of the CC BY 4.0 license.)

Published
2021
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28. Eukaryotic cell biology is temporally coordinated to support the energetic demands of protein homeostasis.

Author

O'Neill JS, Hoyle NP, Robertson JB, Edgar RS, Beale AD, Peak-Chew SY, Day J, Costa ASH, Frezza C, and Causton HC

Subjects
Autophagy physiology, Bioreactors, Circadian Rhythm, Glycogen metabolism, Heat-Shock Response, Ionomycin, Mechanistic Target of Rapamycin Complex 1 metabolism, Metabolomics, Molecular Chaperones, Osmolar Concentration, Osmotic Pressure, Oxygen metabolism, Protein Biosynthesis, Protein Processing, Post-Translational, Proteome, Proteomics, Ribosomes, Yeasts physiology, Energy Metabolism physiology, Eukaryotic Cells physiology, Proteostasis physiology
Abstract

Yeast physiology is temporally regulated, this becomes apparent under nutrient-limited conditions and results in respiratory oscillations (YROs). YROs share features with circadian rhythms and interact with, but are independent of, the cell division cycle. Here, we show that YROs minimise energy expenditure by restricting protein synthesis until sufficient resources are stored, while maintaining osmotic homeostasis and protein quality control. Although nutrient supply is constant, cells sequester and store metabolic resources via increased transport, autophagy and biomolecular condensation. Replete stores trigger increased H + export which stimulates TORC1 and liberates proteasomes, ribosomes, chaperones and metabolic enzymes from non-membrane bound compartments. This facilitates translational bursting, liquidation of storage carbohydrates, increased ATP turnover, and the export of osmolytes. We propose that dynamic regulation of ion transport and metabolic plasticity are required to maintain osmotic and protein homeostasis during remodelling of eukaryotic proteomes, and that bioenergetic constraints selected for temporal organisation that promotes oscillatory behaviour.

Published
2020
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29. Energetic substrate availability regulates synchronous activity in an excitatory neural network.

Author

Tourigny DS, Karim MKA, Echeveste R, Kotter MRN, and O'Neill JS

Subjects
Astrocytes metabolism, Cell Line, Glucose, Humans, Energy Metabolism, Human Embryonic Stem Cells metabolism, Models, Neurological, Nerve Net metabolism, Synapses metabolism, Synaptic Transmission
Abstract

Neural networks are required to meet significant metabolic demands associated with performing sophisticated computational tasks in the brain. The necessity for efficient transmission of information imposes stringent constraints on the metabolic pathways that can be used for energy generation at the synapse, and thus low availability of energetic substrates can reduce the efficacy of synaptic function. Here we study the effects of energetic substrate availability on global neural network behavior and find that glucose alone can sustain excitatory neurotransmission required to generate high-frequency synchronous bursting that emerges in culture. In contrast, obligatory oxidative energetic substrates such as lactate and pyruvate are unable to substitute for glucose, indicating that processes involving glucose metabolism form the primary energy-generating pathways supporting coordinated network activity. Our experimental results are discussed in the context of the role that metabolism plays in supporting the performance of individual synapses, including the relative contributions from postsynaptic responses, astrocytes, and presynaptic vesicle cycling. We propose a simple computational model for our excitatory cultures that accurately captures the inability of metabolically compromised synapses to sustain synchronous bursting when extracellular glucose is depleted., Competing Interests: The authors have declared that no competing interests exist.

Published
2019
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30. Insulin/IGF-1 Drives PERIOD Synthesis to Entrain Circadian Rhythms with Feeding Time.

Author

Crosby P, Hamnett R, Putker M, Hoyle NP, Reed M, Karam CJ, Maywood ES, Stangherlin A, Chesham JE, Hayter EA, Rosenbrier-Ribeiro L, Newham P, Clevers H, Bechtold DA, and O'Neill JS

Subjects
Animals, Circadian Rhythm physiology, Female, Insulin metabolism, Insulin-Like Growth Factor I metabolism, Male, Mammals metabolism, Mice, Mice, Inbred C57BL, Receptor, IGF Type 1 metabolism, Signal Transduction, Circadian Clocks physiology, Feeding Behavior physiology, Period Circadian Proteins metabolism
Abstract

In mammals, endogenous circadian clocks sense and respond to daily feeding and lighting cues, adjusting internal ∼24 h rhythms to resonate with, and anticipate, external cycles of day and night. The mechanism underlying circadian entrainment to feeding time is critical for understanding why mistimed feeding, as occurs during shift work, disrupts circadian physiology, a state that is associated with increased incidence of chronic diseases such as type 2 (T2) diabetes. We show that feeding-regulated hormones insulin and insulin-like growth factor 1 (IGF-1) reset circadian clocks in vivo and in vitro by induction of PERIOD proteins, and mistimed insulin signaling disrupts circadian organization of mouse behavior and clock gene expression. Insulin and IGF-1 receptor signaling is sufficient to determine essential circadian parameters, principally via increased PERIOD protein synthesis. This requires coincident mechanistic target of rapamycin (mTOR) activation, increased phosphoinositide signaling, and microRNA downregulation. Besides its well-known homeostatic functions, we propose insulin and IGF-1 are primary signals of feeding time to cellular clocks throughout the body., (Copyright © 2019 MRC Laboratory of Molecular Biology. Published by Elsevier Inc. All rights reserved.)

Published
2019
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31. Casein Kinase 1 Underlies Temperature Compensation of Circadian Rhythms in Human Red Blood Cells.

Author

Beale AD, Kruchek E, Kitcatt SJ, Henslee EA, Parry JSW, Braun G, Jabr R, von Schantz M, O'Neill JS, and Labeed FH

Subjects
Casein Kinase Ialpha antagonists & inhibitors, Enzyme Inhibitors pharmacology, Humans, Male, Staurosporine pharmacology, Casein Kinase Ialpha physiology, Circadian Clocks genetics, Circadian Rhythm, Erythrocytes metabolism, Erythrocytes physiology, Temperature
Abstract

Temperature compensation and period determination by casein kinase 1 (CK1) are conserved features of eukaryotic circadian rhythms, whereas the clock gene transcription factors that facilitate daily gene expression rhythms differ between phylogenetic kingdoms. Human red blood cells (RBCs) exhibit temperature-compensated circadian rhythms, which, because RBCs lack nuclei, must occur in the absence of a circadian transcription-translation feedback loop. We tested whether period determination and temperature compensation are dependent on CKs in RBCs. As with nucleated cell types, broad-spectrum kinase inhibition with staurosporine lengthened the period of the RBC clock at 37°C, with more specific inhibition of CK1 and CK2 also eliciting robust changes in circadian period. Strikingly, inhibition of CK1 abolished temperature compensation and increased the Q 10 for the period of oscillation in RBCs, similar to observations in nucleated cells. This indicates that CK1 activity is essential for circadian rhythms irrespective of the presence or absence of clock gene expression cycles.

Published
2019
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32. Signal Transduction: Magnesium Manifests as a Second Messenger.

Author

Stangherlin A and O'Neill JS

Subjects
Cytoplasm, Signal Transduction, gamma-Aminobutyric Acid, Magnesium, Second Messenger Systems
Abstract

Mg 2+ is an essential ion for the cell but whether it can act as a bona fide second messenger has long been questioned. A recent study supports this hypothesis and shows a signalling role for Mg 2+ in GABA-mediated neuronal maturation., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published
2018
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33. Non-transcriptional processes in circadian rhythm generation.

Author

Wong DC and O'Neill JS

Abstract

'Biological clocks' orchestrate mammalian biology to a daily rhythm. Whilst 'clock gene' transcriptional circuits impart rhythmic regulation to myriad cellular systems, our picture of the biochemical mechanisms that determine their circadian (∼24 hour) period is incomplete. Here we consider the evidence supporting different models for circadian rhythm generation in mammalian cells in light of evolutionary factors. We find it plausible that the circadian timekeeping mechanism in mammalian cells is primarily protein-based, signalling biological timing information to the nucleus by the post-translational regulation of transcription factor activity, with transcriptional feedback imparting robustness to the oscillation via hysteresis. We conclude by suggesting experiments that might distinguish this model from competing paradigms.

Published
2018
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34. Mammalian Circadian Period, But Not Phase and Amplitude, Is Robust Against Redox and Metabolic Perturbations.

Author

Putker M, Crosby P, Feeney KA, Hoyle NP, Costa ASH, Gaude E, Frezza C, and O'Neill JS

Subjects
Animals, Glycolysis genetics, Mammals genetics, Mammals metabolism, NAD metabolism, Pentose Phosphate Pathway genetics, Peroxiredoxins metabolism, Circadian Clocks genetics, Circadian Rhythm genetics, Homeostasis
Abstract

Aims: Circadian rhythms permeate all levels of biology to temporally regulate cell and whole-body physiology, although the cell-autonomous mechanism that confers ∼24-h periodicity is incompletely understood. Reports describing circadian oscillations of over-oxidized peroxiredoxin abundance have suggested that redox signaling plays an important role in the timekeeping mechanism. Here, we tested the functional contribution that redox state and primary metabolism make to mammalian cellular timekeeping., Results: We found a circadian rhythm in flux through primary glucose metabolic pathways, indicating rhythmic NAD(P)H production. Using pharmacological and genetic perturbations, however, we found that timekeeping was insensitive to changes in glycolytic flux, whereas oxidative pentose phosphate pathway (PPP) inhibition and other chronic redox stressors primarily affected circadian gene expression amplitude, not periodicity. Finally, acute changes in redox state decreased PER2 protein stability, phase dependently, to alter the subsequent phase of oscillation., Innovation: Circadian rhythms in primary cellular metabolism and redox state have been proposed to play a role in the cellular timekeeping mechanism. We present experimental data testing that hypothesis., Conclusion: Circadian flux through primary metabolism is cell autonomous, driving rhythmic NAD(P) + redox cofactor turnover and maintaining a redox balance that is permissive for circadian gene expression cycles. Redox homeostasis and PPP flux, but not glycolysis, are necessary to maintain clock amplitude, but neither redox nor glucose metabolism determines circadian period. Furthermore, cellular rhythms are sensitive to acute changes in redox balance, at least partly through regulation of PER protein. Redox and metabolic state are, thus, both inputs and outputs, but not state variables, of cellular circadian timekeeping. Antioxid. Redox Signal. 28, 507-520.

Published
2018
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35. NADH Shuttling Couples Cytosolic Reductive Carboxylation of Glutamine with Glycolysis in Cells with Mitochondrial Dysfunction.

Author

Gaude E, Schmidt C, Gammage PA, Dugourd A, Blacker T, Chew SP, Saez-Rodriguez J, O'Neill JS, Szabadkai G, Minczuk M, and Frezza C

Subjects
Bone Neoplasms genetics, Bone Neoplasms metabolism, Bone Neoplasms pathology, Cell Movement, Citric Acid Cycle, DNA, Mitochondrial genetics, Energy Metabolism, Female, Glucose metabolism, Glycolysis, Humans, Mitochondria metabolism, Osteosarcoma genetics, Osteosarcoma metabolism, Oxidation-Reduction, Tumor Cells, Cultured, Cytosol metabolism, Glutamine metabolism, Malate Dehydrogenase metabolism, Mitochondria pathology, NAD metabolism, Osteosarcoma pathology
Abstract

The bioenergetics and molecular determinants of the metabolic response to mitochondrial dysfunction are incompletely understood, in part due to a lack of appropriate isogenic cellular models of primary mitochondrial defects. Here, we capitalize on a recently developed cell model with defined levels of m.8993T>G mutation heteroplasmy, mTUNE, to investigate the metabolic underpinnings of mitochondrial dysfunction. We found that impaired utilization of reduced nicotinamide adenine dinucleotide (NADH) by the mitochondrial respiratory chain leads to cytosolic reductive carboxylation of glutamine as a new mechanism for cytosol-confined NADH recycling supported by malate dehydrogenase 1 (MDH1). We also observed that increased glycolysis in cells with mitochondrial dysfunction is associated with increased cell migration in an MDH1-dependent fashion. Our results describe a novel link between glycolysis and mitochondrial dysfunction mediated by reductive carboxylation of glutamine., (Copyright © 2018 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published
2018
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36. Flexible Measurement of Bioluminescent Reporters Using an Automated Longitudinal Luciferase Imaging Gas- and Temperature-optimized Recorder (ALLIGATOR).

Author

Crosby P, Hoyle NP, and O'Neill JS

Subjects
Gene Expression, Humans, Temperature, Luciferases genetics, Luminescent Measurements methods
Abstract

Luciferase-based reporters of cellular gene expression are in widespread use for both longitudinal and end-point assays of biological activity. In circadian rhythms research, for example, clock gene fusions with firefly luciferase give rise to robust rhythms in cellular bioluminescence that persist over many days. Technical limitations associated with photomultiplier tubes (PMT) or conventional microscopy-based methods for bioluminescence quantification have typically demanded that cells and tissues be maintained under quite non-physiological conditions during recording, with a trade-off between sensitivity and throughput. Here, we report a refinement of prior methods that allows long-term bioluminescence imaging with high sensitivity and throughput which supports a broad range of culture conditions, including variable gas and humidity control, and that accepts many different tissue culture plates and dishes. This automated longitudinal luciferase imaging gas- and temperature-optimized recorder (ALLIGATOR) also allows the observation of spatial variations in luciferase expression across a cell monolayer or tissue, which cannot readily be observed by traditional methods. We highlight how the ALLIGATOR provides vastly increased flexibility for the detection of luciferase activity when compared with existing methods.

Published
2017
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37. Rhythmic potassium transport regulates the circadian clock in human red blood cells.

Author

Henslee EA, Crosby P, Kitcatt SJ, Parry JSW, Bernardini A, Abdallat RG, Braun G, Fatoyinbo HO, Harrison EJ, Edgar RS, Hoettges KF, Reddy AB, Jabr RI, von Schantz M, O'Neill JS, and Labeed FH

Subjects
Electrophysiological Phenomena, Humans, Peroxiredoxins metabolism, RNA, Messenger analysis, Transcription, Genetic, Circadian Clocks physiology, Circadian Rhythm physiology, Erythrocytes metabolism, Potassium metabolism
Abstract

Circadian rhythms organize many aspects of cell biology and physiology to a daily temporal program that depends on clock gene expression cycles in most mammalian cell types. However, circadian rhythms are also observed in isolated mammalian red blood cells (RBCs), which lack nuclei, suggesting the existence of post-translational cellular clock mechanisms in these cells. Here we show using electrophysiological and pharmacological approaches that human RBCs display circadian regulation of membrane conductance and cytoplasmic conductivity that depends on the cycling of cytoplasmic K + levels. Using pharmacological intervention and ion replacement, we show that inhibition of K + transport abolishes RBC electrophysiological rhythms. Our results suggest that in the absence of conventional transcription cycles, RBCs maintain a circadian rhythm in membrane electrophysiology through dynamic regulation of K + transport.

Published
2017
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38. Circadian actin dynamics drive rhythmic fibroblast mobilization during wound healing.

Author

Hoyle NP, Seinkmane E, Putker M, Feeney KA, Krogager TP, Chesham JE, Bray LK, Thomas JM, Dunn K, Blaikley J, and O'Neill JS

Subjects
Burns pathology, Circadian Clocks, Humans, Keratinocytes pathology, Polymerization, Proteome metabolism, Actins metabolism, Circadian Rhythm, Fibroblasts metabolism, Fibroblasts pathology, Wound Healing
Abstract

Fibroblasts are primary cellular protagonists of wound healing. They also exhibit circadian timekeeping, which imparts an approximately 24-hour rhythm to their biological function. We interrogated the functional consequences of the cell-autonomous clockwork in fibroblasts using a proteome-wide screen for rhythmically expressed proteins. We observed temporal coordination of actin regulators that drives cell-intrinsic rhythms in actin dynamics. In consequence, the cellular clock modulates the efficiency of actin-dependent processes such as cell migration and adhesion, which ultimately affect the efficacy of wound healing. Accordingly, skin wounds incurred during a mouse's active phase exhibited increased fibroblast invasion in vivo and ex vivo, as well as in cultured fibroblasts and keratinocytes. Our experimental results correlate with the observation that the time of injury significantly affects healing after burns in humans, with daytime wounds healing ~60% faster than nighttime wounds. We suggest that circadian regulation of the cytoskeleton influences wound-healing efficacy from the cellular to the organismal scale., (Copyright © 2017 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published
2017
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40. In-depth Characterization of Firefly Luciferase as a Reporter of Circadian Gene Expression in Mammalian Cells.

Author

Feeney KA, Putker M, Brancaccio M, and O'Neill JS

Subjects
Animals, Cell Line, Cell Line, Tumor, Circadian Rhythm, Fibroblasts cytology, Firefly Luciferin metabolism, Humans, Kinetics, Luciferases, Firefly genetics, Luminescent Measurements methods, Mice, Period Circadian Proteins genetics, Suprachiasmatic Nucleus metabolism, Time Factors, Fibroblasts metabolism, Luciferases, Firefly metabolism, Period Circadian Proteins metabolism
Abstract

Firefly luciferase (Fluc) is frequently used to report circadian gene expression rhythms in mammalian cells and tissues. During longitudinal assays it is generally assumed that enzymatic substrates are in saturating excess, such that total bioluminescence is directly proportional to Fluc protein level. To test this assumption, we compared the enzyme kinetics of purified luciferase with its activity in mammalian cells. We found that Fluc activity in solution has a lower Michaelis constant (K m ) for luciferin, lower temperature dependence, and lower catalytic half-life than Fluc in cells. In consequence, extracellular luciferin concentration significantly affects the apparent circadian amplitude and phase of the widely used PER2::LUC reporter in cultured fibroblasts, but not in SCN, and we suggest that this arises from differences in plasma membrane luciferin transporter activity. We found that at very high concentrations (>1 mM), luciferin lengthens circadian period, in both fibroblasts and organotypic SCN slices. We conclude that the amplitude and phase of circadian gene expression inferred from bioluminescence recordings should be treated with some caution, and we suggest that optimal luciferin concentration should be determined empirically for each luciferase reporter and cell type., Competing Interests: The author(s) have no potential conflicts of interest with respect to the research, authorship, and/or publication of this article.

Published
2016
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42. Flyglow: Single-fly observations of simultaneous molecular and behavioural circadian oscillations in controls and an Alzheimer's model.

Author

Khabirova E, Chen KF, O'Neill JS, and Crowther DC

Abstract

Circadian rhythms are essential for health and are frequently disturbed in disease. A full understanding of the causal relationships between behavioural and molecular circadian rhythms requires simultaneous longitudinal observations over time in individual organisms. Current experimental paradigms require the measurement of each rhythm separately across distinct populations of experimental organisms, rendering the comparability of the resulting datasets uncertain. We therefore developed FLYGLOW, an assay using clock gene controlled luciferase expression detected by exquisitely sensitive EM-CCD imaging, to enable simultaneous quantification of parameters including locomotor, sleep consolidation and molecular rhythms in single flies over days/weeks. FLYGLOW combines all the strengths of existing techniques, and also allows powerful multiparametric paired statistics. We found the age-related transition from rhythmicity to arrhythmicity for each parameter occurs unpredictably, with some flies showing loss of one or more rhythms during middle-age. Using single-fly correlation analysis of rhythm robustness and period we demonstrated the independence of the peripheral clock from circadian behaviours in wild type flies as well as in an Alzheimer's model. FLYGLOW is a useful tool for investigating the deterioration of behavioural and molecular rhythms in ageing and neurodegeneration. This approach may be applied more broadly within behavioural neurogenetics research.

Published
2016
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43. The Pentose Phosphate Pathway Regulates the Circadian Clock.

Author

Rey G, Valekunja UK, Feeney KA, Wulund L, Milev NB, Stangherlin A, Ansel-Bollepalli L, Velagapudi V, O'Neill JS, and Reddy AB

Subjects
Animals, Base Sequence, Behavior, Animal, CLOCK Proteins genetics, CLOCK Proteins metabolism, Cell Line, Drosophila melanogaster physiology, Gene Expression Regulation, Humans, Mammals physiology, NADP metabolism, NF-E2-Related Factor 2 metabolism, Organ Specificity genetics, Oxidation-Reduction, Signal Transduction genetics, Transcription, Genetic, Circadian Clocks genetics, Pentose Phosphate Pathway genetics
Abstract

The circadian clock is a ubiquitous timekeeping system that organizes the behavior and physiology of organisms over the day and night. Current models rely on transcriptional networks that coordinate circadian gene expression of thousands of transcripts. However, recent studies have uncovered phylogenetically conserved redox rhythms that can occur independently of transcriptional cycles. Here we identify the pentose phosphate pathway (PPP), a critical source of the redox cofactor NADPH, as an important regulator of redox and transcriptional oscillations. Our results show that genetic and pharmacological inhibition of the PPP prolongs the period of circadian rhythms in human cells, mouse tissues, and fruit flies. These metabolic manipulations also cause a remodeling of circadian gene expression programs that involves the circadian transcription factors BMAL1 and CLOCK, and the redox-sensitive transcription factor NRF2. Thus, the PPP regulates circadian rhythms via NADPH metabolism, suggesting a pivotal role for NADPH availability in circadian timekeeping., (Copyright © 2016 The Authors. Published by Elsevier Inc. All rights reserved.)

Published
2016
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44. Cell autonomous regulation of herpes and influenza virus infection by the circadian clock.

Author

Edgar RS, Stangherlin A, Nagy AD, Nicoll MP, Efstathiou S, O'Neill JS, and Reddy AB

Subjects
ARNTL Transcription Factors deficiency, Animals, Biological Transport, CLOCK Proteins genetics, CLOCK Proteins metabolism, Cell Line, Chromatin Assembly and Disassembly, Circadian Rhythm genetics, Cricetinae, Epithelial Cells metabolism, Epithelial Cells virology, Female, Gene Expression Regulation, Genes, Reporter, Herpes Simplex genetics, Herpes Simplex metabolism, Herpesviridae Infections genetics, Herpesviridae Infections metabolism, Herpesvirus 1, Human pathogenicity, Herpesvirus 1, Human physiology, Influenza A Virus, H1N1 Subtype pathogenicity, Influenza A Virus, H1N1 Subtype physiology, Luciferases genetics, Luciferases metabolism, Mice, Mice, Knockout, Orthomyxoviridae Infections genetics, Orthomyxoviridae Infections metabolism, Rhadinovirus pathogenicity, Rhadinovirus physiology, Tumor Virus Infections genetics, Tumor Virus Infections metabolism, Virus Replication, ARNTL Transcription Factors genetics, Circadian Clocks genetics, Herpes Simplex virology, Herpesviridae Infections virology, Host-Pathogen Interactions, Orthomyxoviridae Infections virology, Tumor Virus Infections virology
Abstract

Viruses are intracellular pathogens that hijack host cell machinery and resources to replicate. Rather than being constant, host physiology is rhythmic, undergoing circadian (∼24 h) oscillations in many virus-relevant pathways, but whether daily rhythms impact on viral replication is unknown. We find that the time of day of host infection regulates virus progression in live mice and individual cells. Furthermore, we demonstrate that herpes and influenza A virus infections are enhanced when host circadian rhythms are abolished by disrupting the key clock gene transcription factor Bmal1. Intracellular trafficking, biosynthetic processes, protein synthesis, and chromatin assembly all contribute to circadian regulation of virus infection. Moreover, herpesviruses differentially target components of the molecular circadian clockwork. Our work demonstrates that viruses exploit the clockwork for their own gain and that the clock represents a novel target for modulating viral replication that extends beyond any single family of these ubiquitous pathogens., Competing Interests: The authors declare no conflict of interest.

Published
2016
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45. Daily magnesium fluxes regulate cellular timekeeping and energy balance.

Author

Feeney KA, Hansen LL, Putker M, Olivares-Yañez C, Day J, Eades LJ, Larrondo LF, Hoyle NP, O'Neill JS, and van Ooijen G

Subjects
Adenosine Triphosphate metabolism, Animals, Cell Line, Chlorophyta cytology, Chlorophyta metabolism, Circadian Clocks genetics, Circadian Rhythm genetics, Feedback, Physiological, Gene Expression Regulation, Humans, Intracellular Space metabolism, Male, Mice, TOR Serine-Threonine Kinases metabolism, Time Factors, Circadian Clocks physiology, Circadian Rhythm physiology, Energy Metabolism, Magnesium metabolism
Abstract

Circadian clocks are fundamental to the biology of most eukaryotes, coordinating behaviour and physiology to resonate with the environmental cycle of day and night through complex networks of clock-controlled genes. A fundamental knowledge gap exists, however, between circadian gene expression cycles and the biochemical mechanisms that ultimately facilitate circadian regulation of cell biology. Here we report circadian rhythms in the intracellular concentration of magnesium ions, [Mg(2+)]i, which act as a cell-autonomous timekeeping component to determine key clock properties both in a human cell line and in a unicellular alga that diverged from each other more than 1 billion years ago. Given the essential role of Mg(2+) as a cofactor for ATP, a functional consequence of [Mg(2+)]i oscillations is dynamic regulation of cellular energy expenditure over the daily cycle. Mechanistically, we find that these rhythms provide bilateral feedback linking rhythmic metabolism to clock-controlled gene expression. The global regulation of nucleotide triphosphate turnover by intracellular Mg(2+) availability has potential to impact upon many of the cell's more than 600 MgATP-dependent enzymes and every cellular system where MgNTP hydrolysis becomes rate limiting. Indeed, we find that circadian control of translation by mTOR is regulated through [Mg(2+)]i oscillations. It will now be important to identify which additional biological processes are subject to this form of regulation in tissues of multicellular organisms such as plants and humans, in the context of health and disease.

Published
2016
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46. Reciprocal Control of the Circadian Clock and Cellular Redox State - a Critical Appraisal.

Author

Putker M and O'Neill JS

Subjects
Animals, Circadian Rhythm, Gene Expression Regulation, Humans, Circadian Clocks, Cysteine metabolism, Oxidation-Reduction
Abstract

Redox signalling comprises the biology of molecular signal transduction mediated by reactive oxygen (or nitrogen) species. By specific and reversible oxidation of redox-sensitive cysteines, many biological processes sense and respond to signals from the intracellular redox environment. Redox signals are therefore important regulators of cellular homeostasis. Recently, it has become apparent that the cellular redox state oscillates in vivo and in vitro, with a period of about one day (circadian). Circadian time-keeping allows cells and organisms to adapt their biology to resonate with the 24-hour cycle of day/night. The importance of this innate biological time-keeping is illustrated by the association of clock disruption with the early onset of several diseases (e.g. type II diabetes, stroke and several forms of cancer). Circadian regulation of cellular redox balance suggests potentially two distinct roles for redox signalling in relation to the cellular clock: one where it is regulated by the clock, and one where it regulates the clock. Here, we introduce the concepts of redox signalling and cellular timekeeping, and then critically appraise the evidence for the reciprocal regulation between cellular redox state and the circadian clock. We conclude there is a substantial body of evidence supporting circadian regulation of cellular redox state, but that it would be premature to conclude that the converse is also true. We therefore propose some approaches that might yield more insight into redox control of cellular timekeeping.

Published
2016
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47. Calcium and SOL Protease Mediate Temperature Resetting of Circadian Clocks.

Author

Tataroglu O, Zhao X, Busza A, Ling J, O'Neill JS, and Emery P

Subjects
Animals, Biological Clocks, Calcium Signaling, Calmodulin metabolism, Calpain, Circadian Rhythm, Male, Mammals physiology, Proteolysis, Circadian Clocks, Drosophila Proteins metabolism, Drosophila melanogaster physiology, Nerve Tissue Proteins metabolism
Abstract

Circadian clocks integrate light and temperature input to remain synchronized with the day/night cycle. Although light input to the clock is well studied, the molecular mechanisms by which circadian clocks respond to temperature remain poorly understood. We found that temperature phase shifts Drosophila circadian clocks through degradation of the pacemaker protein TIM. This degradation is mechanistically distinct from photic CRY-dependent TIM degradation. Thermal TIM degradation is triggered by cytosolic calcium increase and CALMODULIN binding to TIM and is mediated by the atypical calpain protease SOL. This thermal input pathway and CRY-dependent light input thus converge on TIM, providing a molecular mechanism for the integration of circadian light and temperature inputs. Mammals use body temperature cycles to keep peripheral clocks synchronized with their brain pacemaker. Interestingly, downregulating the mammalian SOL homolog SOLH blocks thermal mPER2 degradation and phase shifts. Thus, we propose that circadian thermosensation in insects and mammals share common principles., (Copyright © 2015 Elsevier Inc. All rights reserved.)

Published
2015
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48. Effects of caffeine on the human circadian clock in vivo and in vitro.

Author

Burke TM, Markwald RR, McHill AW, Chinoy ED, Snider JA, Bessman SC, Jung CM, O'Neill JS, and Wright KP Jr

Subjects
Adult, Analysis of Variance, Biosensing Techniques, Cell Line, Tumor, Cyclic AMP metabolism, Dose-Response Relationship, Drug, Double-Blind Method, Female, Healthy Volunteers, Humans, Luminescence, Male, Melatonin metabolism, RNA, Small Interfering metabolism, Young Adult, Caffeine therapeutic use, Circadian Clocks drug effects, Circadian Rhythm drug effects
Abstract

Caffeine's wakefulness-promoting and sleep-disrupting effects are well established, yet whether caffeine affects human circadian timing is unknown. We show that evening caffeine consumption delays the human circadian melatonin rhythm in vivo and that chronic application of caffeine lengthens the circadian period of molecular oscillations in vitro, primarily with an adenosine receptor/cyclic adenosine monophosphate (AMP)-dependent mechanism. In a double-blind, placebo-controlled, ~49-day long, within-subject study, we found that consumption of a caffeine dose equivalent to that in a double espresso 3 hours before habitual bedtime induced a ~40-min phase delay of the circadian melatonin rhythm in humans. This magnitude of delay was nearly half of the magnitude of the phase-delaying response induced by exposure to 3 hours of evening bright light (~3000 lux, ~7 W/m(2)) that began at habitual bedtime. Furthermore, using human osteosarcoma U2OS cells expressing clock gene luciferase reporters, we found a dose-dependent lengthening of the circadian period by caffeine. By pharmacological dissection and small interfering RNA knockdown, we established that perturbation of adenosine receptor signaling, but not ryanodine receptor or phosphodiesterase activity, was sufficient to account for caffeine's effects on cellular timekeeping. We also used a cyclic AMP biosensor to show that caffeine increased cyclic AMP levels, indicating that caffeine influenced a core component of the cellular circadian clock. Together, our findings demonstrate that caffeine influences human circadian timing, showing one way that the world's most widely consumed psychoactive drug affects human physiology., (Copyright © 2015, American Association for the Advancement of Science.)

Published
2015
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50. Metabolic Cycles in Yeast Share Features Conserved among Circadian Rhythms.

Author

Causton HC, Feeney KA, Ziegler CA, and O'Neill JS

Subjects
Animals, Casein Kinase I genetics, Cell Division genetics, Glycogen Synthase Kinase 3 genetics, Oxidation-Reduction, Peroxiredoxins metabolism, Phosphorylation, Yeasts, CLOCK Proteins metabolism, Casein Kinase I metabolism, Circadian Clocks physiology, Circadian Rhythm physiology, Glycogen Synthase Kinase 3 metabolism, Phylogeny
Abstract

Cell-autonomous circadian rhythms allow organisms to temporally orchestrate their internal state to anticipate and/or resonate with the external environment. Although ∼24-hr periodicity is observed across aerobic eukaryotes, the central mechanism has been hard to dissect because few simple models exist, and known clock proteins are not conserved across phylogenetic kingdoms. In contrast, contributions to circadian rhythmicity made by a handful of post-translational mechanisms, such as phosphorylation of clock proteins by casein kinase 1 (CK1) and glycogen synthase kinase 3 (GSK3), appear conserved among phyla. These kinases have many other essential cellular functions and are better conserved in their contribution to timekeeping than any of the clock proteins they phosphorylate. Rhythmic oscillations in cellular redox state are another universal feature of circadian timekeeping, e.g., over-oxidation cycles of abundant peroxiredoxin proteins. Here, we use comparative chronobiology to distinguish fundamental clock mechanisms from species and/or tissue-specific adaptations and thereby identify features shared between circadian rhythms in mammalian cells and non-circadian temperature-compensated respiratory oscillations in budding yeast. We find that both types of oscillations are coupled with the cell division cycle, exhibit period determination by CK1 and GSK3, and have peroxiredoxin over-oxidation cycles. We also explore how peroxiredoxins contribute to YROs. Our data point to common mechanisms underlying both YROs and circadian rhythms and suggest two interpretations: either certain biochemical systems are simply permissive for cellular oscillations (with frequencies from hours to days) or this commonality arose via divergence from an ancestral cellular clock., (Copyright © 2015 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published
2015
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